用于工艺开发的具有固液流动的小型化管式冷却结晶器

ASME 2018 16th International Conference on Nanochannels, Microchannels, and Minichannels Pub Date : 2018-06-10 DOI:10.1115/ICNMM2018-7660

Mira Schmalenberg, L. Hohmann, N. Kockmann

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引用次数: 4

摘要

精细化学品和药品的生产通常包括固液悬浮流程。为了实现连续冷却，设计了一种基于螺旋流逆变器(CFI)概念的管状结晶器，该结晶器提供了一个狭窄的液相停留时间分布(RTD)。逆流冷却允许轴向温度曲线的平稳调整。在一个内径为4毫米的原型中，成功地运行了高达50 g min - 1，缩小到一个内径为1.6毫米，长度从7.8到54.6米不等的管中管CFI结晶器(CFIC)。这导致在工艺开发中的化学品消耗显著降低，总质量流率为15-20 g min−1。由于模块化设计，在恒定质量流量下，平均停留时间(3.8 ~ 6.9 min)和平均冷却速率(0.6 ~ 1.4 K·min−1)发生变化。采用l -丙氨酸/水测试系统和125 ~ 180 μm种子晶体分析结晶生长速率和产率。

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Miniaturized Tubular Cooling Crystallizer With Solid-Liquid Flow for Process Development

Production of fine chemicals and pharmaceuticals often includes solid-liquid suspension flow. For continuous cooling a tubular crystallizer was designed based on the coiled flow inverter (CFI) concept, providing a narrow residence time distribution (RTD) of the liquid phase. Counter-current cooling allows for a smooth adjustment of the axial temperature profile. Successful operation of up to 50 g min−1 in a prototype with 4 mm inner diameter was scaled down to a tube-in-tube CFI crystallizer (CFIC) with an inner diameter of 1.6 mm and varying length from 7.8 to 54.6 m. This leads to a significantly lower consumption of chemicals in process development with lower total mass flow rates of 15–20 g min−1. Due to modular design, mean residence time (3.8 to 6.9 min) and mean cooling rate (0.6 to 1.4 K·min−1) were varied at constant mass flow rate. Crystallization growth rate and yield are analyzed with the L-alanine/water test system and seed crystals of 125–180 μm.

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ASME 2018 16th International Conference on Nanochannels, Microchannels, and Minichannels

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